Regenerative medicine
leverages the innate potential of the human
body to efficiently repair and regenerate damaged tissues using engineered
biomaterials. By designing responsive biomaterials with the appropriate
biophysical and biochemical characteristics, cellular response can
be modulated to direct tissue healing. Recently, inorganic biomaterials
have been shown to regulate cellular responses including cell–cell
and cell–matrix interactions. Moreover, ions released from
these mineral-based biomaterials play a vital role in defining cell
identity, as well as driving tissue-specific functions. The intrinsic
properties of inorganic biomaterials, such as the release of bioactive
ions (e.g., Ca, Mg, Sr, Si, B, Fe, Cu, Zn, Cr, Co, Mo, Mn, Au, Ag,
V, Eu, and La), can be leveraged to induce phenotypic changes in cells
or modulate the immune microenvironment to direct tissue healing and
regeneration. Biophysical characteristics of biomaterials, such as
topography, charge, size, electrostatic interactions, and stiffness
can be modulated by addition of inorganic micro- and nanoparticles
to polymeric networks have also been shown to play an important role
in their biological response. In this Review, we discuss the recent
emergence of inorganic biomaterials to harness the innate regenerative
potential of the body. Specifically, we will discuss various biophysical
or biochemical effects of inorganic-based materials in directing cellular
response for regenerative medicine applications.
